Method of providing an access request to a same server based on a unique identifier

ABSTRACT

Typically, within most networks, user information takes time to propagate from one server to another to ensure that critical information is uniform throughout the network. Therefore when a user logs-in to the network it is important for the end user computer terminal to authenticate the user against the most current user information before granting the user access to the network. In many cases the user information is not updated immediately across the entire network and therefore the same user wishing to obtain access from another terminal within the network may be declined access. Therefore it would be advantageous to transform data unique to the user to determine a value indicative of a same destination server for serving the access request, regardless of the end user client terminal from which access is desired.

FIELD OF THE INVENTION

[0001] This invention generally relates to user password authentication within a computer network and more specifically to the area of using LDAP servers for ensuring a user is authenticated on a server within the network even when a portion of the user login information has changed and the updated information has not had time to propagate throughout the network.

BACKGROUND OF THE INVENTION

[0002] In recent years, computer networks have grown both in size and in the number of services that a network can provide. The services provided by a computer network are accessible by end users if they have required access for the desired service. To the end user, the fact that there are multiple servers on the network is usually transparent. Login information for a user may be contained on at least one of a number of servers within the network. Typically, within most networks, user information propagates over time from one server to another to ensure that critical information is uniform throughout the network. Therefore when a user logs-in to the network it is important for the end user computer terminal to authenticate the user against the most current user information before granting access.

[0003] In a large network when a user changes some of their information, such as a login password, it is important to store this modified information somewhere within the network such that when re-authentication is required this information is readily accessible to grant the end user access. Usually within a network the passwords are stored on one of the servers within the network and typically this information is stored on a server that is in direct communication with the client terminal.

[0004] For example an end user modifies their login password, the end user password is now updated and saved on a first server in direct communication with the client terminal. The user now moves to another location within the network and logs-in on a different client terminal connected to a different second server within the network. After logging-in the second server initiates the user verification process. After the verification process the user is declined access to the network, and a message appears that the user password is invalid. The user now re-types their login information using their old password and now gains access to the network.

[0005] In this scenario the user password was initially only changed on the first server in direct communication with the client terminal, the information has not had enough time to propagated through the network; resulting in the user being declined access by using their new password, and still having access with the old password. In order for the new user password to work on all the servers the user must wait for the updated password information to propagate through all the servers within the network before obtaining access to their account.

[0006] Of course it would be possible for the end user to utilize both passwords while logging-in to the network while the updated password propagates through the system. However using two passwords for a certain amount of time is disadvantageous and in some cases prohibitive for obtaining full network services. For instance in a large organization there are external peripheral devices, like printers, hooked up to the servers on the network. Because of billing issues the printer requires a user ID and password before processing any print jobs. The user now wishes to print, however their password has not yet propagated through to the printer server. Therefore at the client terminal the new user password may work for the first server, however when this server sends the print job to the printer server the print job will be rejected because of an invalid user password. For the end user this makes the network services inaccessible since at random the user may be prompted that their password is invalid. This dual password disadvantage means that users will change their passwords less frequently thereby possibly compromising network security.

[0007] It is therefore an object of this invention to provide a computer network which allows the user to change their personal profile (i.e. password) from any client terminal on the network, such that when the user logs-in to the network from any other client terminal their personal profile information will always be retrieved from a same server; thereby eliminating the need for having two different user passwords stored on the network.

SUMMARY OF THE INVENTION

[0008] In accordance with the invention there is provided a method of directing a server access request comprising the steps of:

[0009] providing a plurality of destination servers;

[0010] providing an access request from a source computer to a first server, the access request including data unique to the source;

[0011] transforming the data unique to the source to determine a value indicative of one of the destination servers for serving the access request; and

[0012] providing the access request to the determined one of the destination servers.

[0013] In accordance with another aspect of the invention there is provided a computer network comprising:

[0014] a plurality of client terminals;

[0015] a plurality of first servers each including a process for selection of a destination server based on information received from a client terminal, wherein same information from a client terminal results in selection of same destination server; and

[0016] a plurality of destination servers.

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The invention will now be described with reference to the drawings in which:

[0018]FIG. 1 is a diagram of a LDAP computer network having client terminals, servers and LDAP servers; and

[0019]FIG. 2 is a flowchart of the user authentication process using an LDAP server.

DETAILED DESCRIPTION OF THE INVENTION

[0020] An ideal method of setting up a computer network that allows for maintaining user access from any client terminal within the network is by using secondary LDAP (Lightweight Directory Access Protocol) servers connected to primary servers within the network. LDAP is a directory service protocol that runs over TCP/IP with the LDAP directory structure based on entries. Each entry is a collection of attributes that has a name. For instance a password field would be considered an entry. This name is used to refer to each entry unambiguously. In LDAP servers the information within the directory entries is arranged in a hierarchical tree-like structure that reflects organizational boundaries within the network. So for instance the user login name would precede the user password in hierarchy. Within the LDAP there are operations for interrogating LDAP directories, updating LDAP directories, adding and deleting entries from a directory, changing existing entries, as well as changing the name of entries. LDAP search operation allows some portion of the directory to be searched for entries that match criteria specified by a search filter. Information can be requested from each entry matching specified criteria.

[0021] In FIG. 1 a LDAP computer network is illustrated. The computer network comprises client terminals 10, first servers 11, destination servers in the form of LDAP servers 13, and a network peripheral device in the form of a printer 12. The client terminals 10 are coupled via network connectivity to the first servers 11 and the first servers are coupled via network connectivity to the LDAP servers 13. Each LDAP server 13 has a network connection to each other LDAP server 13 via first servers 11 within the network. However, each client terminal is not coupled via network connectivity to each first server 11. So for instance client terminal 14 is only coupled to first servers 15 and 16, and not to 17. Therefore any information entered at client terminal 14 passes through one of the first servers 15 or 16 to get to LDAP servers 13. Each of the client terminals 10 within the network has a unique IP address associated with the client terminal.

[0022] After user information has been changed on a single LDAP server 13, it will take some time for the information to migrate through to the other LDAP servers connected to the network. Therefore it is advantageous to direct server access requests as shown in FIG. 2.

[0023] In FIG. 2, a method of directing a server access request is shown. At the client terminal 10 a user attempts to login to the network. The user accesses a biometric authentication process that authenticates their biometric information and then retrieves password data from an LDAP server 13 on the network. Thus, once authenticated, a data request and an IP address of the client terminal is provided to one of the first servers 11. The first server 11 hashes the IP address, for example, provided to the client terminal and uses this mathematical transform to obtain an identification or selection criteria for one of the LDAP servers 13 for processing the data access request. If this LDAP server happens to be inoperative or unresponsive, then the user access request is provided to a different LDAP server within the network based on modifying the determined identification or selection criteria in a predetermined fashion.

[0024] The first server 11 connects to the determined LDAP server 13 and requests the data in accordance with the data access request. The LDAP server responds with the data, or with a pointer to the data. Typically, each LDAP server is identical to each other—exact mirrors—though there is a known time lag in data update between LDAP servers 13. A data access request presented to one LDAP server references the same entry it would at another LDAP server. Therefore whenever a piece of user information is changed on a single LDAP server it will eventually propagate to the other LDAP servers and, as such, can be accessed from any of the LDAP servers 13. Advantageously, while the information is propagating and before it has completed propagation, the user is able to enjoy full network access and full access to most current LDAP data including using new password or entry code information since access requests are directed to the same LDAP server based on an IP address.

[0025] Advantageously, with relation to user data access requests from LDAP servers 13, the first servers 11 may remain stateless, in that the first servers 11 need no prior dynamic knowledge about the network or past data access requests in order to accurately provide the advantages of the present invention. First servers 11 within the network only require network topology knowledge and knowledge of the predetermined processes used to select an LDAP server 13.

[0026] Alternatively, a step of re-hashing the IP address is performed. In an alternative embodiment a user specific data value in the form of a login name or a PIN is hashed such that a same user accesses a same LDAP server 13 each time a data request is provided for processing by the LDAP servers 13. As such, even when a user changes locations or computers, the same LDAP server is accessed by any of that user's requests.

[0027] Numerous other embodiments may be envisaged without departing from the spirit or scope of the invention. 

What is claimed is:
 1. A method of directing a server access request comprising the steps of: providing a plurality of destination servers; providing an access request from a source computer to a first server, the access request including data unique to the source; transforming the data unique to the source to determine a value indicative of one of the destination servers for serving the access request; and providing the access request to the determined one of the destination servers.
 2. A method according to claim 1 comprising the step of providing a plurality of first servers, wherein the plurality of first servers are disposed within a network and wherein each server of the plurality of first servers performs a same transform on the data unique to a source such that data from a same source is provided to a same destination server by each of the plurality of first servers.
 3. A method according to claim 2 wherein the plurality of first servers operate in a stateless fashion in respect of access requests to the destination servers.
 4. A method according to claim 3 wherein if a destination server is inoperative data unique to the source is transformed again to obtain a second other destination server.
 5. A method according to claim 3 wherein if a destination server is inoperative the first server according to a same predetermined process as the other first servers obtains a second other destination server.
 6. A method according to claim 1 wherein the data unique to the source comprises of the end user login identification.
 7. A method according to claim 6 wherein the destination servers are LDAP servers within the network.
 8. A method according to claim 7 wherein information stored on an LDAP server takes a finite time to migrate to other LDAP servers within the network.
 9. A method according to claim 8 wherein request is a request for security data.
 10. A method according to claim 9 wherein the security data includes access codes and wherein upon changing an access code the data stored within a single LDAP server is updated and then, at a later time propagated to other LDAP servers within the network and wherein a same source retrieves the updated information upon accessing an LDAP server via any of the plurality of first servers.
 11. A method according to claim 2 wherein the security data includes access codes and wherein upon changing an access code the data stored within a single destination server is updated and then, at a later time propagated to other destination servers within the network and wherein a same source retrieves the updated information upon accessing a destination server via any of the plurality of first servers.
 12. A method according to claim 10 wherein while the changed access code and data is propagating through LDAP servers within the network the end user has full access to most current LDAP data including new password or entry code information since access requests are directed to the same LDAP server based on an IP address.
 13. A method according to claim 5 including the step of: providing the plurality of first servers within the network with network topology knowledge.
 14. A method according to claim 13 including the step of: providing the plurality of first servers within the network with instructions for carrying a predetermined process for selecting a LDAP server.
 15. A method according to claim 2 comprising the steps of: providing biometric information; performing a biometric authentication process for authenticating the provided biometric information to provide a value indicative of an identification; and, providing password data from an LDAP server in dependence upon the value.
 16. A computer network comprising: a plurality of client terminals; a plurality of first servers each including a process for selection of a destination server based on information received from a client terminal, wherein same information from a client terminal results in selection of same destination server; and a plurality of destination servers.
 17. A computer network according to claim 16 wherein: the plurality of destination servers are LDAP servers. 